Plating method and apparatus for controlling deposition on predetermined portions of a workpiece
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
C23C-018/00
C23C-014/00
C25D-005/02
C25D-005/34
C25D-005/18
출원번호
US-0961193
(2001-09-20)
발명자
/ 주소
Basol, Bulent M.
출원인 / 주소
ASM Nutool, Inc.
대리인 / 주소
Knobbe Martens Olson &
인용정보
피인용 횟수 :
20인용 특허 :
4
초록▼
The present invention relates to methods and apparatus for plating a conductive material on a workpiece surface in a highly desirable manner. Using a workpiece-surface-influencing device, such as a mask or sweeper, that preferentially contacts the top surface of the workpiece, relative movement betw
The present invention relates to methods and apparatus for plating a conductive material on a workpiece surface in a highly desirable manner. Using a workpiece-surface-influencing device, such as a mask or sweeper, that preferentially contacts the top surface of the workpiece, relative movement between the workpiece and the workpiece-surface-influencing device is established so that an additive in the electrolyte solution disposed on the workpiece and which is adsorbed onto the top surface is removed or otherwise its amount or concentration changed with respect to the additive on the cavity surface of the workpiece. Plating of the conductive material can place prior to, during and after usage of the workpiece-surface-influencing device, particularly after the workpiece surface influencing device no longer contacts any portion of the top surface of the workpiece, to achieve desirable semiconductor structures.
대표청구항▼
1. A method of plating a conductive top surface of a workpiece, the conductive top surface of the workpiece including a top portion and a cavity portion, the method comprising:applying, over the conductive top surface of the workpiece, an electrolyte solution with at least one additive disposed ther
1. A method of plating a conductive top surface of a workpiece, the conductive top surface of the workpiece including a top portion and a cavity portion, the method comprising:applying, over the conductive top surface of the workpiece, an electrolyte solution with at least one additive disposed therein, a first portion of the additive becoming adsorbed on the top portion and a second portion of the additive becoming adsorbed on the cavity portion; using a workpiece-surface-influencing device to make physical contact with the top portion and establishing relative movement with the workpiece to change at least the first portion of the additive adsorbed onto the top portion; moving the workpiece-surface influencing device relatively away from the workpiece surface so that the physical contact between the workpiece-surface-influencing device and the workpiece no longer occurs; and plating the conductive top surface of the workpiece with a conductor obtained from the electrolyte solution at least during a period of time when at least some of the change is maintained and while the workpiece-surface-influencing device remains moved relatively away from the workpiece surface, thereby causing greater plating of the cavity portion relative to the top portion. 2. The method according to claim 1 further comprising further plating the conductive top surface of the workpiece before and during the steps of using and moving.3. The method according to claim 2 wherein the steps of using the workpiece-surface-influencing device, moving the workpiece-surface-influencing device, and plating are repeated.4. The method according to claim 2, wherein the step of plating continues without further contact being established between the workpiece-surface-influencing device and the workpiece surface to result in an overfill of the conductor being plated over the cavity portion relative to the top portion of the workpiece surface.5. The method according to claim 2 wherein the conductive top surface includes a plurality of cavity portions, and the step of plating plates a conductive layer over the conductive top surface, such that the conductive layer is formed within each of the plurality of cavities, is formed over a flat top surface portion of the conductive top surface with a substantially planar thickness, and is formed over at least one of the plurality of cavity portions with a thickness that is greater than the substantially planar thickness to create an overfill thereover.6. The method according to claim 5 wherein the one cavity portion is larger than a plurality of other cavity portions, and the plurality of other cavity portions have formed thereover the thickness of the conductive layer that is greater than the substantially planar thickness to create at least one another overfill thereover, and the one cavity portion has formed thereover the thickness of the conductive layer that is greater than the substantially planar thickness to create the overfill.7. The method according to claim 2 further comprising the steps, after the step of plating, of:re-using the workpiece-surface-influencing device to make physical contact with the top portion and establishing relative movement with the workpiece to obtain another change in at least the first portion of the additive adsorbed onto the top portion; again moving the workpiece-surface-influencing device relatively away from the workpiece so that the physical contact between the workpiece surface influencing device and the workpiece no longer occurs; and again plating the conductive surface of the workpiece with the conductor obtained from the electrolyte solution during another period of time when at least some of the another change is maintained. 8. The method according to claim 7 wherein the conductive top surface includes a plurality of cavity portions and one cavity is larger than a plurality of other cavity portions, and the step of again plating plates a conductive layer over the conductive top surface, such that the conductive layer is formed within each of the plurality of cavities, is formed over a flat top surface portion of the conductive top surface with a substantially planar thickness, is formed over the plurality of other cavity portions with a substantially planar thickness and is formed over at least the one cavity portion with a thickness that is greater than the substantially planar thickness to create an overfill thereover.9. The method according to claim 1 wherein the at least one additive includes a plurality of additives, comprising both a suppressor and an accelerator.10. The method according to claim 9 wherein the plurality of additives includes Cl.11. The method according to claim 9 wherein, during the step of plating, more effective accelerating additive exists on the cavity portion than on the top portion.12. The method according to claim 1 wherein the step of using the workpiece-surface-influencing device creates the change by at least one of removing accelerator species, activating suppressor species, and increasing suppressor species on the top portion.13. The method according to claim 12 wherein the steps of using the workpiece-surface-influencing device, moving the workpiece-surface-influencing device, and plating are repeated.14. The method according to claim 1 wherein the step of plating includes the step of providing at least one of DC, AC and pulsed power during plating.15. The method according to claim 14 wherein the step of providing provides DC power and operates, at least part of the time in a current controlled mode in which a plating current is substantially controlled.16. The method according to claim 14 wherein the step of providing provides DC power and operates, at least part of the time in a voltage controlled mode in which a plating voltage is substantially controlled.17. The method according to claim 1 wherein the conductor comprises one of copper or a copper alloy.18. The method according to claim 1 wherein power used for plating is not applied during the steps of using and moving.19. The method according to claim 1 wherein the step of using the workpiece-surface-influencing device causes a differential in a surface resistance between the top portion and the cavity portion.20. The method according to claim 1 further comprising the step of adding another additive to the electrolyte that assists in loosening a bond between the additive and the surface of the workpiece.21. A method of plating a conductive top surface of a workpiece, the conductive top surface of the workpiece including a top portion and a cavity portion, the method comprising:applying, over the conductive top surface of the workpiece, an electrolyte solution with at least one additive disposed therein, a first portion of the additive becoming adsorbed on the top portion and a second portion of the additive becoming adsorbed on the cavity portion; using a workpiece-surface-influencing device to make physical contact with the top portion and establishing relative movement with the workpiece to change at least the first portion of the additive adsorbed onto the top portion, wherein using the workpiece-surface-influencing device applies a mask that includes at least one opening therein through which a flow of electrolyte therethrough can be controlled; moving the workpiece-surface influencing device relatively away from the workpiece surface so that the physical contact between the workpiece-surface-influencing device and the workpiece no longer occurs; plating the conductive top surface of the workpiece with a conductor obtained from the electrolyte solution at least during a period of time when at least some of the change is maintained and while the workpiece-surface-influencing device remains moved relatively away from the workpiece surface, thereby causing greater plating of the cavity portion relative to the top portion; and plating the conductive top surface of the workpiece before and during the steps of using and moving. 22. The method according to claim 21 wherein the step of moving the mask away is performed by increasing a pressure of the electrolyte on the mask.23. A method of plating a conductive top surface of a workpiece, the conductive top surface of the workpiece including a top portion and a cavity portion, the method comprising:applying, over the conductive top surface of the workpiece, an electrolyte solution with at least one additive disposed therein, a first portion of the additive becoming adsorbed on the top portion and a second portion of the additive becoming adsorbed on the cavity portion; using a workpiece-surface-influencing device to make physical contact with the top portion and establishing relative movement with the workpiece to change at least the first portion of the additive adsorbed onto the top portion, wherein the step of using the workpiece-surface-influencing device uses a sweeper that has a sweeping portion that physically contacts the workpiece with a surface area that is substantially less than the surface area of the workpiece surface; moving the workpiece-surface influencing device relatively away from the workpiece surface so that the physical contact between the workpiece-surface-influencing device and the workpiece no longer occurs; and plating the conductive top surface of the workpiece with a conductor obtained from the electrolyte solution at least during a period of time when at least some of the change is maintained and while the workpiece-surface-influencing device remains moved relatively away from the workpiece surface, thereby causing greater plating of the cavity portion relative to the top portion. 24. The method according to claim 23 wherein the at least one additive includes a plurality of additives, comprising both a suppressor and an accelerator.25. The method according to claim 24 wherein, during the step of plating, more effective accelerating additive exists on the cavity portion than on the top portion.26. The method according to claim 24 wherein the step of using the workpiece-surface-influencing device creates the change by at least one of removing accelerator species, activating suppressor species on the top portion and increasing suppressor species on the top portion.27. The method according to claim 26 wherein the steps of using the workpiece-surface-influencing device, moving the workpiece-surface-influencing device, and plating are repeated.28. The method according to claim 23, wherein the step of using the workpiece-surface-influencing device ensures that the relative movement causes the change over an entire surface area of the workpiece to be plated.29. The method according to claim 23 wherein the at least one additive includes a plurality of additives, comprising both a suppressor and an accelerator.30. The method according to claim 29 wherein the plurality of additives includes Cl.31. The method according to claim 29 wherein, during the step of plating, more effective accelerating additive exists on the cavity portion than on the top portion.32. The method according to claim 29 wherein the step of using the workpiece-surface-influencing device creates the change by at least one of removing accelerator species, activating suppressor species, and increasing suppressor species on the top portion.33. The method according to claim 23 wherein the steps of using the workpiece-surface-influencing device, moving the workpiece-surface-influencing device, and plating are repeated.
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